Electric circuit



May l, 1945.- l. F, ELCHE 2,374,974

' ELECTRIC CIRCUIT Filed oct. 22, 1942 2 sheets-sheet 1 May 1, 1945. L. F. BLU-ME 2,374,974,

ELECTRIC CIRCUIT Filed oct. 22, 1942 2 sheets-sheet 2 Inventor: Louis F." Blume,

' ci ZM b5 elayAtgorneg.

Patented May 1, 1945 ELECTRIC CIRCUIT Louis F. Blume, Pittsfield, Mass., assigno'r to General Electric Company, a corporation of New York Application October 22, 194,2,l Serial No. 462,945

18 Claims. (C'l. 171-119) This'nvention` relates to the control of electric circuits and more particularly to the switching of alternating currents.

By the term switching is meant either the absolute interruption of a current so that it no longer exists anywhere or the relative interruption of a current whereby, for example, the currentis transferred from one conductor or branch circuit to another one. General purpose switching is of the absolute interruption type but there are a number of special purpose switching arrangements of the relative interruption type.

While thepresent invention is useful in both types of switching, it has been found'especially useful in circuits of the latter type for changing transformer taps under load, such as used in the speed control of electric locomotives and inthe voltage control of `electric power distribution systems and of large industrial loads. In this rapidly growing field of tap-changing, the switches, called in the trade contactors and used for local current interruption during the transfer of the load from one tap to anothenhave now practically reached the limit o f their capacities,

especially under short-circuit conditions, and itv was the needfor greatly increased contac r capacities that stimulated the present inventi n.

Making these contactors` bigger and better isA not an, altogether satisfactory solution of the problem, because itA involves not only an added cost burden but also, in the case of electric locoresult is further improved by the use of immotives particularly, the problem vof finding space Y.

for bigger contactors.

In accordance Vwith thepresent invention a plurality of impedors having different impedance angles are connected' with the switch or contacter in such a way that they enable it to interrupt greatly increased rcurrentswithout a proportionate increase in bulk and cost. By

.,impedorf is meant a device whose primary purpose is to introduce impedance into an electric circuit. It is generic to resistor and reactor, these being devices whose primaiypurpose is to introduce resistance and reactance respectively into an electric circuit. Reactor, in turn, is subgeneric to inductor and capacitor, these being deviceswhose primary purpose is to introduce inductance or inductive reactance and capacitance or capacitive reactance respectively into an electric circuit. By impedance angle of an impedor is meant the phase angle between an alternating current flowing through it and the' voltage drop across it caused by this current. The switch or contacter is provided with at least two sets of contacts which may or may not operate together mechanically but which are connected differently with respect. to the impedors so as to provide a multi-step switching system in which the two sets of contacts operate electrically, or clear, in sequence and not together.

Thus the current is reduced in steps before nalr interruption and also the phase of the. switch voltage is shifted relative to the current whereby the effective interrupting capacity of the sys-l pedors whose impedance values are not constant but vary with the value of the current they carry. Magnetic saturation in the case of an inductor and high positive temperature coeiiicient of rev sistance in the case of a resistor give the desired non-linearity in volt-ampere characteristic.

An object of the invention is to provide a new and improved electric switching method and system.

Another object of the invention is to provide a novel and simple arrangement which enables switchgear to perform greatly increased interrupting duties.

A further object of the invention is to provide an improved arcing contacter system for transformer tap-changing-under-load circuits.

The invention will be better understood from the following description taken in connection with the accompanying drawings and its scope will be pointed out in the appended claims.

In the drawingain which like reference characters designate the same elements throughout the different views, Fig. 1 is a diagrammatic representation of what is called in the art a load ratio control transformer with taps and auxiliary equipment for changing the connections'of said taps to a circuit under load, without interrupting that load, modied in accordance with the present invention. Figs. 2,'3, and 4 represent intermediate positions of the tap-changing equipment of Fig. l during a tap-changing cycle of operations, Figs. 5 and 6 depict the current and voltage phenomena during a tap-changing operation, and help explain the performance and benets of the invention, Fig. 7 is a modication of Fig. 1 for a more economical use of switching equipment, Figs. 8, 9, and 10 illustrate three different applications of the invention to general .purpose circuit-breaker duty, and Fig. ll-represents an equivalent impedance network of the `system of Fig. 10.

Considering now Fig. l, II represents in conventional diagrammatic manner the low voltage winding of a transformer, and I2 its high voltage winding with terminal conductors I3' and I3" leading to either a source or a load (not shown). In the present case the load may also be a short circuit. Winding I2 is shown with a set of taps connected to stationary contact members I4, I5, I6, and I1. Conductor I3 is selectively connected to any one of these stationary contacts byl means of a tap-changing equipment comprising two movable contact members I8 and I9;`

and 24 and the operations associated wtih them, (2) .the structure of the preventive autotransformer, and (3) the structure or coordination or both of the resistors, contactors and the autotransformer so as to be able to change taps under larger load conditions than has been possible heretofore.

According to the present invention, the preventive autotransformer 26 is designed with a ferro-magnetic core with or without a gap in it, the cross sectionI of the core and the number of turns of the winding being so proportioned that the core does not become. magnetically saturated when the winding is subjected to the tap voltage in the bridging position. The core may become, but need not become, saturated under the magnetizing action of the normal rated load current when the entire line current flows through one half of its winding, as when the circuit of one of the parallel paths of the tap changer is interrupted and the entire current is constrained to flow in the other path, as illustrated in Fig. 3. It is, however, so constructed that if, under this circuit condition, with the entire load current flowing in only one half of the winding of the autotransformer` the current should very greatly exceed the continuous' current capacity of the circuit, as when theload becomes accidentally short-circuited, the core of 26 will become magnetically saturated by the current during at least an appreciable fraction of each half cycle of the current wave. i

In order better to explain the current and voltage phenomena quantitatively, the curves of Fig. 5 have been plotted for the application of the f invention to a typical circuit of which the normal rated load is 5400 kva.. the rated voltage of winding I2 is 13,200 volts (root-mean-square value), hence the rated load currentl in conductor I3' is 409 amperes (root-mean-square value). -In the ,full cycle operating position of the movable contact members I8 and I9 on the same xed contact the normal current in each half of pre ventive 'autotransformer 26 will therefore equal 204.5 amperes (root-mean-square value). rI'he voltage of each tap step, such as the voltage between I5 and I 6, is assumed to be 2.5 per cent of the rated voltage of Winding I2, that is, 330 volts. The preventive autotransforme'r is assumed to have a small gap in its core, andthe magnetizing reactance, X, of its full winding (a4-b) is assumed to be 1.61 ohms so as to yield, in the bridging position, a circulating current of 204.5 amperes, equal to the normal rated current in each winding section a and b. We shall refer to this reactance value as the unsaturated reactance value of winding 26. The leakage reactance between winding sections a and b is low enough to be negligible compared with the magnetizing reactance of 26. The magnetizing reactance of each winding section a and b will then be a quarter of that of the full winding, that is approximately 0.4 ohm. This also will be approximately the value of the mutual reactance between a and b.

The voltage drop across winding section a for rated load in the quarter-cycle position shown in Fig. 3 will then be equal to one half of the tap-to-tap voltage.

The core of 26 saturates sharply and its reactance drops from 1.61 to 0.112 ohm when an unbalanced or circulating current of 354 amperes instantaneous value flows through its full winding. 'Ihis current will be seen to be about 22 per cent higher than the crest of the circulating current in the bridging position illustrated in Fig. 4. The saturated reactance value indicated above is what is variously called the instantaneous or incremental value.

It is further assumed that the short-circuit current in the lines I3', I3 is ten times the normal rated load current in those lines, that is, 4090 amperes (root-meamsquare value). In considering the duty of the tap-changing equipment under such high short-circuit currents, it is permissible to ignore the circulating current in the bridging position (Fig. 4) so as to simplify explanations. The optimum value of the resistance, R, of 2| (also of 22) may be determined by investigating the effect of various values of it. The curves of Fig. 5 are based on R=X/3.

Considering now Fig. 5, time is indicated as moving from left to right, and the interval To to T1 applies to the circuit condition represented by Fig. 1 during a short circuit between conductors I3 and I3". The single curve shown in this time -interval and marked Ie and It represents the equal currents in the two parallel paths discussed above in connection with Fig. 1, with a' maximum'instantaneous value of 2900 amperes. During this interval, To to T1, there is no appreciable resistance or reactance drop between contact I5 and conductor I3', because each one of the resistors 20 and 2l is short-circuited and the preventive autotransformer offers only a leakage reactance to this distribution of current though its two halves.

At time T1, when these current Wavesare passing through zero, contactor 24 is in the open position shown in Fig. 2, and the current path through it is definitely interrupted. The current, It, is now constrained to ow through resistor 2| and with a changed value, so that Ia and Ib are now different curves, It larger and Ib smaller than before. The voltage drop across 2I is equal to lbR, and its curve is identified in Fig. 5 by eR. As Is and It are not equal now, their difference magnetizes the autotransformer and causes a magnetizing reactance voltage across the full winding of 26. The curve of this voltage is identified in Fig. 5 by ex. a time interval T1 to T2 the curves eR and ex coincide with each other and appear as one curve. This arises from the fact that, under the circuit condition of Fig. 2, between the points I5 and 25 considered as two junction points, the resistor 2| and the winding 26 are in parallel with each other, and therefore their voltages must be alike. This voltage appears across the gap of contac- Ator 24.

At time T2, the resultant magnetizing eiect of Ia and Ib (each onel flowing in one half of the winding of 26 and in opposition to the other) carries the magnetization of the core of 26 to saturation density, and the (solid) curves of both current and voltage are assumed to make asharp bend here. The dotted continuations of the curves show what the phenomena would be if the core did not saturate.

At time T3, the current Ib, which ilows through contactor 25. is passing through zero. The reason Ia now leads Ib in time phase by approximately It will be observed that, in the 4- arc previous to this instant, there is a good likelihood oi the arc going out completely at this, in-l stantv so that current will not be reestablished through contacter 25. When that happens the reactance voltage eX reverses rather abruptly to the small value of about '15 volts negative and then 'rises slowlyfin'the negative direction to a value of V'approximately 300 volts through the time interval Ts tov'I's. The reason for the reversal'of exis' that Is has passed its peak value and is now decreasing whereas before it had been increasing. I

As Ib is zero after time Ta and only Is flows in v26, therefore, Ia, being entirely unbalanced, magnetizes and saturates the core of 26. It is seen that during this time, and up to instant Te, Is is diminsimilar to those of the resistance 2l in whichl case ishing and hence its magnetizing effect is dimin-4 ishing.

' At the instant T5, the magnetization of the core of 26 has diminished to the borderline value below which the core is unsaturated; and as the magnetization drops below this value, the reactance voltage -drop increases relatively,abruptly to the value of approximately 3700 volts.

If the gap of ccntactor 25 resists reignition of an arc at the earlier instant T3, and stays eleotrically unbroken through the intervalTs-'to Ts,

2,374,974 f l f the duty on resistor 2l is reduced and 2| can be of a smaller kilowatt rating and cost. In the extremely-high-current circuits, the arc across 24 might be utilized as the resistor 2l to realize a considerable fraction of the benefit from the saturation of 26.

The sequence of the opening of contactors 24 and 25 (similarly, 22 and 23) pointed out above is to be understood as the sequence of the stopy page of the current through them, rather. than it need not break down under the high reactance voltage at the instant T5, because meanwhile the gap has become larger and more completely deionized. That is, the more critical time for contactor 25 to break down is the instant T3, rather than T5.

1f 2s did not saturate, the current Ib through contacter 25 would follow the dotted extension of the'curve and have a somewhat higher peak value than the solid branch of the curve and would pass.

through zero at the instant T4. If the arc through the gap of 25 should go out at this instant, and the current not become re-'established through it, the voltage eX, which appears across this gap, would take a sudden plunge to about 3200 volts. While this voltage of the non-saturating reactance at time T4 is somewhat less than that oi the saturating reactance at time T5, the former isv far more dangerous than the latter, because it comes on when the current is passing through zero and the gap that was arcing has not had an appreciable chance to deionize itself and therefore has an extremely low dielectric strength; whereas the latter, coming on at time T5, about 67 degrees later than the instant Ta of the interruption of the current, is easily resisted by the gap because it is practically completely deionized and has regained its dielectric strength. The relative recovery-voltage duty on contactor 25, with and without saturation in 26, is therefore in the ratio of the T3 value of eX to its T4 value, that is, in the ratio of to 3200; and this illustrates the important role of saturation in the invention.

The fact discussed in the preceding paragraph brings out one of the important features of the present invention; namely, that while ordinarily, when switching an inductive circuit, the maximum voltage across the gap of a switch coincides with the instant of the interruption of the current. In the arrangement of the present invention these two happenings, that is, the current zero and the recovery-voltage maximum, are separated from each other by a considerable time interval, allowing time for the gap to deionize and recover atleast a substantial portion of its maximum dielectric strength before being subjected to the crest voltage. We may say that the current and the recovery-voltage waves are deoftheir mechanical operation for it -is permissible that 24 and 25 open .mechanically together. When their mechanical opening is simultaneous,

`both will be bridged by arcs, but the arc across A 24 will go out more easily and therefore first,

`the arc across 25 going out a substantial fraction of a cycle afterwards, as illustrated by Fig. 5. Fig. 6 is similar to Fig. 5 except that here R .y is assumed to have an extremely high value, in-

comparably large in relation to X, so as to bring out the significance of the roleplayed by resistance of appropriate value according to the present invention. vAccordingly, we assume R equal to innity. This would be represented by disconnecting fromI the circuit the resistors 2D and 2|. Considering the curves of Fig. 6, the single curve`of current during the interval To to T1 applies to the state of the system shown in Fig. 1. At instantv'IH contacter 24 is open as shown in Fig. 2, and the current through 24 is denitely interrupted. As the resistance of 2l is assumed large enough to be practically equivalent to open circuit, the wave of In ends at this instant and is not rre-established, the entire current iiowing into I3 now-nowing through 22 as Is. At instant T2 saturation sets in, and the solid extension of the curve of Ia represents the saturated condition upto time T4. 'Ihe dotted extension of the curve representsv the current when the inductor 26 does not saturate at all,

During the interval To to'Ti Athe reactancey voltage is merely a leakage-reactance drop and therefore negligible, but immediately subsequent to time T1 when Ib .fails to be re-established and the entire current supplied tov I3 flows through the`winding section a. exclusively, this current magnetizes the core of 26, .and theY resulting voltage drop across the full winding of 26 jumps to the value of approximately 3675 Volts as represented by the curve of eX at T1. The inductor may be saturable,` but at this time it cannot be saturated because the total ampere-turns acting on it is zero. If saturable as in the preceding case, saturation will set in at the instant T2, and the voltage will then drop from 3600 volts to the low value of 300 volts, but this reduction, though desirable, is of no significant help to the interrupting ability of the contactor because interruption of current belongs to the instant T1 when the current is passing through zero, and at that instant there is a recovery voltage of 3675 volts tending to restrike the arc if the current should fail to be re-established. Note that the crest of the recovery-voltage wave eX coincides with the zero of the current It to be interrupted, that is, the dephasing phenomenon pointed out above in connection with Fig. is absent here.

Although current interruption phenomena are very complex, involving some factors which are not yet thoroughly understood, still it is generally agreed that alternating-current interrupting duty on a switch is proportional to the kva. obtained by multiplying the R. M. S. (root-meansquare) value of the current wave through the switch with the time rate of rise of the recovery voltage across it. Accordingly, the duty imposed on the contactors in the present invention may be estimated as follows. It will be evident by symmetry that'the duty on 22 will be similar to that on 24, and the duty on 23 similar to that on 25.

Considering now the duty on contacter 24, we find from Fig. 5 that the R. M. S. value of the current wave through contactor 24 is 2060 amperes under short circuit, and that the rate of rise of the recovery voltage at time T1 (when the current through 24 is interrupted), that is, the slope of eR is 0568x106 volts per second, assuming that the frequency of the alternating current is sixty cycles, making the interrupting duty on contacter 24 equal to 1.17 106 kva.

Considering the duty on contactor 25, its maximum current, assuming the reactance saturable, occurs at the instant T2 (Fig. 5) with an R. M. S. value of approximately 1100 amperes. of rise of recovery voltage at the time of current interruption occurs at the instant T3 with a value which depends on the oscillatory frequency of the circuit. Although the voltage ex, about 75 volts.

at T3, is shown for convenience as if rising to this value instantaneously, actually it rises tc this value in a finite though very small time interval, through a series oi' damped oscillations of very high frequencycharacteristic of the circuit, as well understood in the circuit-breaker art. This frequency varies from circuit to circuit and through a wide range, from a few thousand cycles to hundreds of thousands of cycles per second. For purposesof illustration, we shall assume that in the present case the oscillatory frequency of the circuit is an intermediate valuesay 10,000 cycles. This makes the maximum rateof rise .of ex during its iirst quarter cycle Yof oscillation equal to 21r 10,000XeX, that is, 1.'77xl0e volts per second, and the kva. duty on contacter 25 becomes 5.25 x 108 y The results of these calculations and similarl other calculations for other assumptions when tabulated give us an exhibit of switching duties as follows:

L r. X Y x X Reactencesaturablei Contractor 24 1.17)(106 3.633100"y 4800Xl0 Contractor25 5.25)(10' 0.736Xl0 0 Reectance nonssturabl Contractor 24.---.- .g 1.17Xl0l 3.63X10 4800 10e Contractor 25 v- BODXIU 126X10 O Its rate' Opens.

actance saturation will reduce the switching duty on the circuit interrupting means by many times, or, alternatively, that a given set of switches can be enabled to control many times as large system kva. as their maximum capacity in the presentday conventional practice.

Fig. 7 illustrates diagrammatically a modification of Fig. 1, wherein the kva interrupting duty imposed on two of the four switches 22, 23,24 and 25 is negligible, and those two will therefore be practically free from arcing, permitting a less expensive construction and yet with an indefinitely long life. In addition, one of the resistors 20 and 2l is eliminated, thus further simplifying the circuit. These results are accomplished by separating the halves a and b of the preventive autotransformer 2G so as to form what might be called a split inductor. Half a is connected between ratio adjuster I8 and main circuit conductor I3 in series with switch 24, and half b isv connected between ratio adjuster I 5 and'main circuit conductor |3''in series with switch 25. Switches 22 and 28 are connected in series with each other between -the terminals of the halves a and b of the re a ctor which are connected respectively tothe switches 24 and 25. The resistor 20 is connected across the switch 22.

The operation of Fig. 7 is as follows: 'I'he parts are shown in their full-cycle position and if it is desired to move ratio adjuster I9 out of engagement with tap contact |15 and into engagement with tap contact I6 so as to pass through the quarter-cycle position to the half-cycle or bridging position the switch 25 is first opened. As this switch is short-circuited by the other three switches it performs practically no arcing duty so that it can be made quite inexpensively. Switches 22 and 23 are now opened either simultaneously or in the order mentioned, thus interrupting the current through the ratio adjuster contact I9, as has previously been explained in connection with Figs. 1-6, inclusive. Contact I9 can now be moved without danger of any arcing .as it is carrying no current and can then be moved into engagement with contact I6. Switches 22 and 23 are then closed and iinally switch 25 is closed. When it is desired to move the ratio adjuster I9, switch 24 is first opened but as this switch is now short-circuited by switches 22, 23 and 25 it will be seen that it performs no arcing duty when it Switches 22 and 23 are then opened thereby to interrupt the current in the ratio adjuster I8.

It should, of course, be understood that the opening of switches 22 and 23 combined with the saturation of the core of the split reactor 26 imposes switching duties on the .switches 22 and 23 which are similar to the switching duties imposed on' the similarly numbered switches in Figs. 1-4, inclusive.

Fig. 8 illustrates diagrammatically a general purpose circuit-breaker application of the invention, that is, its application to the interruption of the short-circuit current of a power system 28,

comprising a generator 30, an impedor 3| representing the generator and. other system impedances and a short circuit at 31. The control means according to the present invention includes the switches 32, 33, and 34, a resistance 35 and a saturable inductor 36. In the normal operation switch 32 interrupts full current, the rate of rise of its recovery voltage isvery small both because the crest value of the recovery voltage is a fraction vof that of the system voltage and (whaty is 'far more important) the front of the wave of the recovery voltage is that of a 60 cycle wave, not an abrupt or high frequency rise. The kva. interrupting duty'on 33 is also a fraction of that of the conventional circuit-breaker duty both because it interrupts only a fraction of the original shortcircuit current and (what is far more important) the interruption takes place at an instant when 36 is saturated and the magnitude of the recovery voltage is a vfraction of the system voltage. Finally, the duty on 34 is reduced because although its recovery voltage is of the same general nature as that of a conventional breaker, the -eiective value of the .current which it'interrupts is reduced with the help of reactor 36 which is absent in conventional breaker practice.

9 is a modification of Fig. 8 in which two resistors instead of one, and four switches instead of three, are utilized. To clear a short circuit at 31, the switches clear in the sequence 4|, 42, 43 and 44.--v They may open in this mechanical sequence or may all open simultaneously.

Y The opening of switch 4I inserts in Vseries with the circuit three impedors, namely, the resistor 35a, the resistor 35h, and the saturable core inductor 36, all three in parallel with each other. 'Ihe opening of switch 42 removes the resistors, leaving only the inductor, whereby the impedance in series with the short circuit is increased. The opening of switch 43 inserts the resistors 35a and 35h in series with the circuit, thereby further increasing the impedance in series with the short circuit. Finally, the opening or switch 44 completely interrupts the flow of current.

Just as the falling orf of the inductance of the inductor element, as by saturation, greatly improves the performance of the invention, so also a falling off of the conductance of the resistor element, asfor instance by an increase in its temperature from the time it is cut into the circuit to the time when it is cut out, improves the performance of the invention. This latter 'advantage results not only from an increase in the dephasing eiect of the resistance, but also from an increase in another effect thereof, namely, the dissipation of the stored energy of the circuit and reduction of the crest voltages and rates of rise of the recovery voltages. As this time interval for the production of this eiect is a very small fraction of a second, and as the permissible temperature rises for circuit elements are generally limited, I propose to utilize for this purpose resistors which have high positive temperature coeiiicients of resistance, such as, for instance, what is known in the trade as hitemco wire, which is characterized with a very rapid falling oi in perature.

Fig. 10 illustrates a modification of Fig. 9 in which the simple inductor 36 of Fig. 8 is replaced by an autotransformer type inductor similar, for instance, to the autotransformer 26 of Fig. l. As the'replaced inductor had two terminals and the replacing inductor has three, the connections of the system are modified by connecting one end of 35 to the intermediate terminal 45 of 26. The steady state equivalent network of this system is shown in Fig. 11 in which 46 and 41 are simple inductors not coupled with each other, and 48 is a capacitor. p

If 45 in Fig. l0 is a midtap terminaLand the winding sections a and b are very closely coupled, then in the -equivalent network shown in Fig. 11, the inductors 46 andv41 will have equal ohmic values,'and 48 will have an ohmic value approximately one-half of that of 46.

While 1there have been shown and described particular embodiments of this invention, it will be obvious to those skilled in the art that various changesand modifications can be made therein without departing from the invention and, therefore, it is aimedin the appended claims to cover all such changes and modifications as fall within the true spirit and scope of. the invention.

What I claim as new and desire to secure by Letters Patent of the United States is:

l. Control means for an alternating-current circuit comprising, in combination, switch means for opening said circuit, at least two impedors having different impedance angles connected into said circuit, the impedance `of one of said inipedors being substantially lvariable under the action of a flow of current therethrough, said impedance variation being independent of the direction of said current flow, and additional switching means for modifying the connections of said impedors in said circuit selectively in a predetermined sequence to reduce the interrupting duty of said first-mentioned switch means.

2. Control means -for an alternating-current circuit comprising, in combination, switch means for opening said circuit, at least two impedors having different impedance angles connected into said circuit, one of said impedors being inductive and having a magnetically saturable core, and additional switch means for modifying the connections of said impedors in said circuit selectively in a predetermined sequence to reduce the interrupting duty of said `first-mentioned switch means.

3. Control means for an alternating-current circuit comprising, in combination, switch means for opening said circuit, at least two impedors having different impedance angles connected into said circuit, one of said impedors being resistive and characterized by a diminishing conductance under the action of a flow of current therethrough regardless of the direction of said flow of current,.and additional switch means for modifying the connections of said impedors in said circuit selectively in la predetermined sequence to reduce the interrupting duty of said rst-mentioned -switch means.

4. Control means for an alternating-current circuit comprising, in combination, switch means for opening said circuit, at least two impedors having different impedance angles connected into said circuit, one of said impedors being inductive and having a magnetically saturable core structure, the other of said impedors being resistive and being characterized by reduced conductance due to an increase in its temperature, and additional switch means for modifying the connections of said impedors in said circuit selectively in a predetermined sequence to reduce the interrupting duty of said first-mentioned switch means.

5. An alternating-current switching system comprising, in combination, an alternating-current circuit, a plurality of impedors having different impedance angles, and a plurality of switches, at least one of said impedors and one of said switches being connected in parallel circuit relation with each other in said circuit whereby the opening of said switch reduces the current in said circuit, said last-mentioned impedor being resistive in character, `at least one other of said impedors and one other of said switches being connected in series circuit relation with each other in said circuit whereby the opening of said other switch interrupts said current, said other impedor being a saturable core inductor.

6. In combination, an alternating-current circuit having at least two parallel branches, impedance means with different impedance `angles connected in said branches, at least one of said impedance means being normally effectively short-circuited, means for opening said short circuit whereby the currents in said branches become dephased, and means for opening. one of said branches.

7. The combination as in claim 6 in which said normally short-circuited impedance means is resistive and the other impedance means is inductive.

8. The combination as in claim 6 in which said normally short-circuited impedance means has a positive temperature coeincient of resistance and the ,other impedance means is a saturable core Vinductor.

9. i The method of interrupting the flow of current in an alternating-current system which includes the steps of (a) introducing impedance in series with a portion of said system to modify the current to be interrupted, (b) opening the circuit current to have a distorted wave shape with a crest value and a zone of substantially lower val- `ues in the neighborhood of said crest value, the time phase of said zone of lower values coinciding with the zero instant of said current to be interrupted.

1G. The method of interrupting the now of current in an alternating-current system which includes the steps of (a) introducing impedance in series with a portion of said system lto modify the current to be interrupted, (b) opening the circuit; of said modiiied current, and (c) distorting the wave shape of the recovery voltage following the interruption of said modied current from a sine wave form so as to provide in the neighborhood of the crest value of a half cycle of said Wave a zone of substantially lower values than correspond to a sine wave of a maxium 'value equal to said crest value and of a frequency equal to the frequency of said voltage.

l1. In an alternating-current system, voltage control means comprising, in combination, a transformer having a winding provided with at least two' taps at different potentials, each one of said taps being connected to a main contact member, a pair of auxiliary contact members arranged to make contact selectively with said main contact members, each one of said pair of auxiliary contact members constituting one ter minal of one of a pair of circuits connected to` gether at their other terminals, each one of said pair of circuits including an inductive element, said inductive elements being closely coupled with each other, switch means for interrupting the iiow of current in one of said circuits, impedance means, and switch means arranged to introduce said impedance means in series with said lastmentioned circuit for dissipating a portion of the energy of said circuitl as a function of said current when said last-mentioned switch means is opened.

12. In combination, a transformer winding having a plurality of taps, a pair of tap changers for selectively making connection to said taps,

a midtapped inductor, a circuit for said winding one side of which is connected to said winding and the ,other side of which is connected to the midtap of said inductor, two pairs of switches serially connected respectively .between said tap changers and the terminals of said inductor, and a pair of resistors connected respectively across one switch of each pair.

13. The combination as in claim 12 in which said inductor has a core which saturates at a value of unbalanced current therethrough which is substantially in excess of the rated current of said winding. Y

14. The combination as in claim 12 in which said resistors have optimum values such that the interrupting duty of the switches of each pair are substantially equal.

l5. In combination, a transformer winding provided with a plurality of taps, a. pairof ratio adjusters for selectively making connection to said taps, a pair of selector switches for respectively connecting said ratio adjusters to one side of a circuit for said winding, a split inductor having its halves serially connected respectively between said ratio adjusters and their associated selector switches, said inductor having a core which saturates when an unbalanced current substantially in excess of the rated current of said circuit ows through its winding, a pair of con tactors connected in series with each other'between the terminals of said selector switches which are connected to said inductor, and a resistor connected across one of said contactors.

16. The combination as in claim 15 in which said contactors are simultaneously operable and said resistor has a relatively high positive temperature coefficient of resistance.

17. In combination, an alternating-current ci'r.

Lome r. nimm. 

